Simulated vernix compositions for skin cleansing and other applications

ABSTRACT

A composition and a method of producing a composition which simulates hydration, cleansing and other properties of native vernix. The composition contains, in one embodiment, hydrated synthetic cells in a lipid matrix to provide properties which are substantially similar to those of native vernix, and may also contain proteins. In one embodiment, the composition contains water-in-oil emulsified particles providing water vapor transport and evaporative water loss properties simulating native vernix. In one embodiment, the composition contains cubosomes/water with up to 30% protein and about 5% lipid to about 30% lipid. The composition may be used to cleanse newborn skin, compromised skin surfaces, as well as normal skin, to provide hydration/barrier function, and other applications.

RELATED APPLICATIONS

This application is a Continuation-in-Part of U.S. application Ser. No. 10/512,933, mailed to the U.S. Patent and Trademark Office via Express Mail No. EV127170350US on Oct. 29, 2004, which is the National Stage of International Application No. PCT/US03/13612 filed May 2, 2003, which claims the benefit of U.S. Provisional Application Ser. No. 60/377,430 filed May 3, 2002, and U.S. Provisional Application Ser. No. 60/439,966 filed Jan. 14, 2003, each of these applications expressly incorporated by reference herein in its entirety.

FIELD OF THE INVENTION

A composition simulating natural vernix and uses for the composition.

BACKGROUND OF THE INVENTION

Vernix caseosa (vernix) is a lipid-rich naturally occurring skin protectant composed of sebum, epidermal lipids, and desquamated epithelial cells. It covers the skin of the developing fetus in utero while the fetus is completely surrounded by amniotic fluid. Vernix consists of hydrated cells dispersed in a lipid matrix. Natural vernix comprises about a 10% lipid fraction by weight, about a 10% protein fraction by weight, and about an 80% volatile fraction by weight. The lipid matrix undergoes a transition to a more fluid form at physiological temperatures and with the application of shear forces, such as those encountered with movement. Vernix is a covering for the skin of the fetus that resembles the stratum corneum except that it lacks multiple rigid desmosomal connections. Consequently, vernix exhibits a viscous fluid character.

The lipid component of vernix has been reported in J. Invest. Dermatol. 78: 291 (1982); Lipids 6: 901 (1972); J. Clin. & Lab. Investigation 13: 70 (1961); J. Invest. Dermatol., 44: 333 (1965); and U.S. Pat. No. 5,631,012, each of which is incorporated by reference herein in its entirety. Lipids, defined herein as fats or fat-like substances, include lecithin and other phospholipids, squalene, waxes, wax esters, sterol esters, diol esters, triglycerides, ceramides in which the fatty acid components may be one or more of the following: α-hydroxy 6-hydroxy-4-sphingenine, α-hydroxy phytosphingosine, α-hydroxy sphingosine, ester linked ω-hydroxy 6-hydroxy-4-sphingenine, non-hydroxy phytosphingosine, non-hydroxy sphingosine, and/or ester linked ω-hydroxysphingosine; free sterols, and four classes of fatty acids ranging in chain length from C₁₂ to C₂₆ (straight chain saturated, chain unsaturated). The lipid fraction may contain, with the relative percentages indicated, squalene (9%), ceramides (10%) aliphatic waxes (12%), sterol esters (33%), diesters (7%), triglycerides (26%), free sterols (9%), and other lipids (4%). The fatty acids within the aliphatic waxes may be branched and the branched fatty acids may be methylated.

Because of its anticipated skin maturation and protectant properties, vernix appears to have promise as a clinically effective therapeutic agent. Application of vernix to clinical use, however, has been limited by the difficulty in obtaining samples of sufficient volume, the possibility of disease transmission, and the physical properties of native vernix.

Regarding its physical properties, vernix in utero is a tractable semi-solid, whereas vernix ex utero is a nonhomogeneous intractable compound with a consistency comparable to cheese or hardened cake frosting. Vernix is not completely soluble in conventional solvents such as absolute ethanol, 95% ethanol, 2-propanol, and combinations of chloroform and methanol. Thus, controlled and uniform administration of vernix to a surface is difficult. While it has been reported that the surfactant polysorbate 80 (Tween 80) may solubilize vernix, we previously reported that Tween 80 is toxic to living cells and therefore cannot be used clinically, i.e. for direct application to compromised skin. Tween 80 may have unwanted longer term effects in some populations. Isolated reports disclose vernix directly scraped from a newborn for smearing over wounds (SU Patent No. 1718947A) or an artificial lipid composition as a cosmetic moisturizer (U.S. Pat. No. 5,631,012).

Natural vernix contains proteins which, in general, are multi-determinant antigens. Thus, the protein component of vernix may be capable of inducing an immune response and reacting with the products of an immune response. Proteins with a greater degree of complexity generally provoke a more vigorous immune response.

The protein fraction of natural vernix consists of epidermally derived proteins, primarily keratin and filaggrin, trace amounts (micromolar to millimolar concentrations) of regulatory proteins such as epidermal growth factor, and trace amounts (nanomolar to micromolar concentrations) of surfactant protein such as surfactant associated protein-A and surfactant associated protein-B.

Because virtually all proteins are immunogenic in an appropriate individual, and because of the different type and complexity of proteins in natural vernix, at least some immune response would be anticipated when vernix is applied to non-self (other than the baby and/or the mother). The response encompasses physical, biochemical, and molecular changes, such as stimulation of T cells, B cells, and macrophages, hypersensitivity reactions or allergic reactions, inflammation, fever, etc.

We have previously reported that synthetic vernix may be produced by mixing one part of natural vernix, removed from the infant at the time of delivery, with any of the following components in the proportions indicated: either about 0.005 to about 0.05 parts phospholipid, or trace amounts of about nanomolar to micromolar concentrations of pulmonary surfactant proteins such as surfactant A and/or surfactant B, or 5 parts dimethylsulfoxide (DMSO), or 1 part amniotic fluid, or combinations of the above. Alternatively, synthetic vernix may also be produced by combining lipids to comprise about a 10% fraction of the entire volume, proteins to comprise about a 10% fraction of the entire volume, and water to comprise the remaining about 80% of the entire volume. The following lipid components are combined in the relative percentages indicated: squalene (9%), aliphatic waxes (12%), sterol esters (33%), diesters (7%), triglycerides (26%), free sterols (9%), and other lipids (4%). The fatty acids within the waxes may be branched and the branched fatty acids may be methylated. The protein components, combined to constitute about a 10% fraction, are epidermally derived proteins, primarily keratin and filaggrin, with trace amounts of about micromolar to millimolar concentrations of regulatory proteins such as epidermal growth factor, and trace amounts of about nanomolar to micromolar concentrations of surfactant protein such as surfactant A and surfactant B.

Skin cleansing formulations generally contain surfactants that emulsify soils on the skin surface for removal with a water rinse. Surfactants may be anionic, cationic, nonionic, or zwitterionic and can be in the form of a bar, a liquid, a cream, a gel, etc. Surfactants vary markedly in their effects on the skin and differ significantly in their inherent irritancy to skin. They have been shown to vary in their effects on corneocyte swelling, disaggregation, and damage. Surfactants, as well as other topical treatments, can vary greatly in their effects on the permeability barrier of skin. For example, the effects of sodium dodecyl sulfate (SDS) and acetone on human skin in vivo (biopsy specimens) were evaluated by electron microscopy. Damage to nucleated epidermal cells and disruption of lipid extrusion were observed for skin treated with 0.5% SDS, even though the upper stratum corneum was intact. Acetone treatment resulted in disruption of epidermal lipid lamellae and loss of lamellar cohesion throughout the stratum corneum.

The amount of residual material left on the skin surface after cleansing depends upon properties of the surfactant, including its interaction with calcium and magnesium in the rinse water. The amount of surfactant used in cleansing and the extent of surfactant dilution with rinsing (i.e., volume of rinse water) can impact the residual material remaining on the skin surface. Procedures for bathing newborns frequently involve minimal rinsing to minimize the cooling effects of full body water exposure. Consequently, due to the low volume and short duration of rinsing, the level of residual surfactant on newborn skin is expected to be high.

Given the irritating and drying effects of surfactants on skin, the advisability of bathing infants with cleansing products warrants re-evaluation. It has been recommended to use mild cleansers with few ingredients to minimize irritant and allergic dermatoses in infants, and to use specialized preparations for specific dermatoses that might occur (J Eur Acad Dermatol Venereol 2001; 15, 12). One of the functions of bathing a newborn is to remove blood and pathogens to prevent transmission to others. A study compared the pathogen colonization rate for a group of 62 infants bathed using a mild cleanser, with the colonization rate for a group of 65 infants bathed with water alone (Birth 2001; 28, 161). Colonization of the skin increased over time in both groups, with no difference in type or quantity of microorganisms. These data indicate that the cleanser does not impact bacterial colonization.

Various cleansing treatments on the skin of infants aged 2 weeks to 16 months were evaluated (Dermatology 1997; 195, 258). Parallel treatment groups of 7-10 infants were washed one time with water alone, a synthetic liquid cleanser, a synthetic bar cleanser, or a fatty acid soap. Measures of skin pH, hydration, and surface lipid content were made before and ten minutes after washing. All four treatments increased the skin pH over its starting pH, with water alone resulting in the smallest pH increase and soap resulting in the largest pH increase. All three cleansers resulted in a significantly greater pH increase than water alone, with the fatty acid soap significantly greater than the synthetic liquid or bar cleanser. The authors indicated that the tap water used in bathing was alkaline (pH 7.8-8.2), but the extraction of water-soluble amino acids in natural moisturizing factor due to bathing is expected to give rise to a higher pH. No differences were detected in skin hydration, either as a result of bathing or the cleansing product. This finding is inconsistent with the results of another study reporting decreased hydration following bathing, but in the latter study, the time after bathing was shorter (10 min versus 15 min), the base sizes of the infants were smaller, and the age ranges differed (3-6 months versus 2 weeks-16 months) (Ped Dermatol 2002; 19, 473). In another study determining the effects of bathing a group of infants over a two week period with a whey-based product, decreased hydration, pH and erythema were reported, but the changes were not statistically significant (Schweiz Rundsch Med Prax 1998; 87, 617).

The effects of water and surfactants can be further exacerbated by pre-existing skin conditions or other environmental factors. The effects of washing with a cleanser on stratum corneum and epidermal thickness were evaluated among normal and atopic (having allergic reactions, e.g., hay fever, asthma, atopic dermatitis) subjects. Soaps decreased the number of cell layers in the atopic subjects but not the normal subjects, suggesting that atopic individuals have increased susceptibility to cleansers.

The combination of washing with surfactants and decreased environmental humidity has also been investigated. In human adults, the effects of irritant dermatitis due to repeated water and/or surfactant exposure were exacerbated at decreased absolute humidity. Animals exposed to low humidity for a short time (two days) exhibited increased epidermal proliferation following surfactant (SDS) exposure, compared to animals housed at normal or high humidity. Additionally, animals exposed to high humidity for two weeks had greater epidermal proliferation after exposure to surfactant than did animals exposed to low or normal humidity for two weeks. This suggests that the effects of water and surfactants may be greater under humidity extremes in either infants or neonates.

Skin of premature neonates has poor epidermal barrier properties and increased susceptibility to damage. These factors, coupled with the overall medical instability of premature infants, must be balanced with the need for practices, such as bathing, to reduce the risk of infection. One study investigated the effects of reduced bathing frequency (once in four days compared to once a day) on skin pathogen colonization among a group of premature infants. No differences were found in skin flora on days 2, 3, or 4 after bathing (J Obstet Gynecol Neonatal Nurs 2000; 29, 584). Reduced bathing frequency for premature infants has been, and continues to be, recommended as a general standard of care in the neonatal nursery (J Obstet Gynecol Neonatal Nurs 1999; 28, 241). The specific effects of bathing on preterm infant physiology and behavior were investigated in a group of ten subjects, with responses measured ten minutes before, during, and ten minutes after the bath. Significant increases were observed for heart rate, cardiac oxygen demand, and motor behavior, accompanied by a significant decrease in oxygen saturation.

Compared to term infants, preterm infants are more susceptible to transdermal exposures due to their immature epidermal barrier. At one time, cleansing products containing 3% hexachlorophene were regularly used for full body bathing of premature neonates, but subsequent evaluations of the neurotoxic effects indicated that vacuolar encephalopathy was related to hexachlorophene exposure. The use of hexachlorophene-containing products was therefore discontinued for this population. Alternatives were proposed through testing on the control of pathogenic bacteria, and included Lactacyd (an alkyl sulfate surfactant) and Hibitane (chlorhexidine). Subsequent evaluation of Lactacyd, however, showed that it increased transepidermal water loss (TEWL) and was inappropriate for premature infants, and chlorhexidine was found to be cytotoxic to fibroblasts and keratinocytes in culture and therefore contraindicated for preterm infants.

Thus, the use of topical products on premature infant skin, including surfactants, cleansers, antiseptics, etc., must be carefully considered. Factors which govern the relative effect on the infant include stratum corneum thickness and integrity, amount of surface residue, inherent irritancy of residual materials, and partition coefficient through the stratum corneum. While the stratum corneum of preterm infants develops rapidly after birth under the influence of the relatively dry environmental condition, the barrier function is not fully competent for several weeks after birth and is more permeable to exogenous materials. In particular, bathing involves minimal rinsing of the skin surface, and thus residual materials remain on the skin surface.

Stratum corneum, the outermost surface of the skin, continually self-cleanses through the process of desquamation. In utero, during the third trimester, vernix gradually detaches from the fetal skin under the influence of mechanical stress and pulmonary surfactant, yielding turbid amniotic fluid. At birth, residual vernix on the skin surface forms the physical interface between the newborn infant and a nonsterile environment.

Most surfactants used in commercially available cleansing products interact with and alter the epidermal barrier, as evidenced by numerous studies using in vivo systems. A consideration of the response of infant skin, versus adult skin, to topically applied treatments is useful in order to determine the potential effects of topical treatments in the preterm infant. For example, the infant has a greater surface area to body weight ratio and absorbs proportionately greater quantities than adults. Tissue distribution depends on age, and tissue affinity may vary between infants and adults, leading to different overall effects.

There is, therefore, a need to determine methods and compositions that are useful in compromised skin, such as that found in a preterm infant having immature epidermal barrier structure and function, as well as normal skin.

SUMMARY OF THE INVENTION

One embodiment of the invention is a simulated vernix composition of hydrated synthetic cells (e.g., cubosomes, polymersomes, water-in-oil emulsions, colloidosomes) dispersed in a lipid matrix. Another embodiment is a simulated vernix composition containing hydrated synthetic cells and proteins (e.g., keratin, filaggrin, epidermal growth factor, surfactant associated protein-A, -B, -D, and the individual amino acids comprising natural moisturizing factor) dispersed in a lipid matrix. The lipid matrix may contain cholesterol, cholesterol esters, ceramides, triglycerides, fatty acids, phospholipids, wax esters, wax diesters, and/or squalene. The lipids constitute about 5 wt % to about 30 wt % of the total composition. The protein, if present, constitutes about 0.1 wt % to about 30 wt % of the total composition.

Another embodiment is a method of treating skin by applying a physiologically compatible composition containing hydrated synthetic cells in a lipid matrix in an amount effective to treat skin. It may be applied to intact or compromised skin, for example, to bring about skin growth, maturation, or healing when applied to a wound or ulcer, or to provide a barrier, such as a water repellent or moisturizing function, when applied to normal, chapped, or irritated skin.

Another embodiment is an apparatus that contains a device for contacting a skin surface (e.g., a pad, bandage, diaper, dressing, etc.) which carries a pharmaceutical composition comprising hydrated synthetic cells in a lipid matrix.

Other embodiments are compositions and methods of treating skin by providing a physiologically compatible composition containing hydrated synthetic cells in a lipid matrix in an amount sufficient such that the composition applied to the skin surface provides various physical properties, such as a minimum surface free energy of about 20 dynes/cm; a contact angle with benzyl alcohol in the range of about 18.0 to about 24.7, a contact angle with diiodomethane in the range of about 30.0 to about 38.3, a contact angle with glycerol in the range of about 71.9 to about 76.5, and a contact angle with water in the range of about 82.7 to about 84.3; a critical surface tension in the range of about 38 dynes/cm to about 41 dynes/cm; a critical surface tension greater than 36 dynes/cm; water vapor transport that ranges between up to about 85% of transport through a substantially highly permeable composition (i.e., one that has greater than about 99% water vapor transport), and down to about 5% of transport through a substantially highly occlusive composition (i.e., one that has less than about 0.5% water vapor transport); or an amount sufficient to effect barrier repair as a semipermeable film.

Another embodiment is a method of using either a natural or synthetic vernix, or a simulated vernix composition, to remove soil from a skin surface. The composition is applied to the soiled surface, then is removed along with the soiling material. The method may be used on a premature or full term infant, a child, an adult, a geriatric patient, and the composition may be used on an intact or compromised surface, such as a wound or ulcer. The method may be used with a vernix composition that also contains a soap and/or surfactant.

Another embodiment is a method for fully or partially cleansing a baby (full term or premature) immediately after birth with a composition containing isolated native vernix or synthetic vernix to remove amniotic fluid, endogenous vernix, meconium, blood and other fluids, upon removing the composition.

Another embodiment is a method of cleaning a soiled skin surface by applying a composition consisting essentially of isolated physiologically compatible vernix or synthetic vernix under conditions to emulsify the soiling material in the vernix, and then removing the vemix and emulsified soiling material. The amount of vernix may be up to about 16 mg/cm².

Another embodiment is a method of cleansing skin by applying a nontoxic film having a thickness up to about 16 mg/cm² and consisting essentially of isolated physiologically compatible vernix to a layer of epithelial cells to provide a skin cleansing effect. The film may be applied either directly or indirectly to the surface; for example, it may be applied to a wash cloth, a wipe, a bandage, a pad, etc. Another embodiment is a method of cleansing an epithelial layer by applying a non-toxic film having a thickness of up to about 16 mg/cm² and consisting essentially of isolated physiologically compatible vernix to the epithelial layer, and then removing the film from the cleansed tissue.

Another embodiment is a method to protect a skin surface of an individual who is, or may be, susceptible to commercially available cleansing products (e.g., one allergic to some commercial soaps or cleansers). In the method, a composition consisting essentially of isolated physiologically compatible vemix or synthetic vemix is applied to a skin surface of this individual in an amount up to 16 mg/cm² before exposing the skin surface to the product.

Another embodiment is a method to remove a soiling material from a skin surface by providing isolated physiologically compatible vernix or synthetic vernix and at least one soap or surfactant to the soiled surface under conditions resulting in flocculation and detachment of the soil from the surface.

Another embodiment is a synthetic vemix composition having a continuous lipid phase where the lipids are substantially physiologic lipids, and a water phase of simulated cells dispersed in the lipid phase, the water phase having greater than about 65% ^(w/w) water of the total composition, with water vapor transport through the composition that ranges between about 85% of water vapor transport through a substantially highly permeable composition and about 5% of water vapor transport through a substantially highly occlusive composition, and a rate of evaporative water loss from the composition from about −38% water in composition/hr to 0% water in composition/hr from 0 h to 0.5 hr, that is, up to about 38% water loss within the first half-hour, and from about −8% water in composition/hr to 0% water in composition/hr from 0.5 hr to 3 hr, that is, up to about 8% water loss after the first half-hour and for the next two and one-half hours.

Another embodiment is a synthetic vernix composition having a lipid phase and a water phase, with the lipid phase having at least one emulsifying agent to form hydratable water-in-oil emulsified particles. The emulsifying agent has a hydrophile-lipophile balance (HLB) value such that the emulsifying agent does not substantially dissolve in the water phase. For example, the HLB value may range between about 3 to about 6.

In one embodiment, the synthetic vernix composition comprises hydratable water-in-oil emulsified particles having a lipid phase comprising lanolin, squalene, linoleic acid, cholesterol, ceramide III, wax, capric/caprilic triglyceride, cholesterol sulfate; PEG30 dipolyhydroxystearate and sorbitan sesquioleate emulsifying agents; a water phase containing methylparaben and/or propylparaben, magnesium sulfate, glycerin, and water; in concentrations sufficient to provide water vapor transport, evaporative water loss, tactile and rheological properties simulating native vernix.

In another embodiment, the synthetic vernix composition comprises hydratable water-in-oil emulsified particles in a lipid phase comprising lanolin, stearyl alcohol, wax, mineral oil, and petrolatum; cetyl dimethicone copolyol and Abil WE09 (polyglyceryl-4-isostearate and cetyl dimethicone copolyol and hexyl laurate) emulsifying agents, and water.

The invention will be further appreciated with respect to the following detailed description, figures, and examples.

BRIEF DESCRIPTION OF THE FIGURES

FIGS. 1A, 1B, and 1C are digital images of hand skin, either unsoiled (FIG. 1A), after application of a soiling material (FIG. 1B), or after application of vernix to the soiled area (FIG. 1C).

FIGS. 2A, 2B, 2C, and 2D are digital images of volar forearm skin, either unsoiled (FIG. 2A), after application of a soiling material (FIG. 2B), or after application of either native vernix (FIG. 2C) or a commercial soap (FIG. 2D) to the soiled area. FIGS. 2E, 2F, and 2G are digital images of volar forearm skin, either unsoiled (FIGS. 2E1 and 2E2), after application of a soiling material (FIGS. 2F1 and 2F2), or after application of a synthetic vernix (FIGS. 2G1 and 2G2).

FIGS. 3A, 3B, 3C, and 3D are histograms quantitating the amount of soiling material on the skin surface of unsoiled (baseline), soiled, and cleansed skin treated with Aquaphor (FIG. 3A), commercial cleansers (FIGS. 3B and 3C), or native vernix (FIG. 3D). FIGS. 3E, 3F, 3G, 3H, 31, and 3J are histograms quantitating the amount of soiling material on the skin surface of unsoiled (baseline), soiled, and cleansed skin treated with water (FIG. 3E), Aquaphor (FIG. 3F), commercial cleansers (FIGS. 3G, 3H), synthetic vernix (FIG. 31), and native vernix (FIG. 3J).

FIGS. 4A, 4B, 4C, and 4D are digital images of skin before soiling and after cleaning with Aquaphor (FIG. 4A), commercial cleansers (FIGS. 4B and 4C), or vernix (FIG. 4D).

FIGS. 5 and 5A are plots of differences in L-scale scores before and after cleansing with various treatments.

FIG. 6 is a representative digital image converted to its black and white counterpart image for native vernix (FIG. 6) and synthetic vernix (FIGS. 6A1-6A6, 6B1-6B6) and correlating photographic images and graphical results (FIG. 6C) for synthetic vernix.

FIG. 7A is a graph showing native vernix detachment in the presence of surfactant from an in vitro surface. FIG. 7B is a histogram showing native vernix detachment in the presence of surfactant from an in vivo surface treated with increasing thickness of a vernix film.

FIGS. 8A, 8B, and 8C show evaporative water loss profiles of embodiments of synthetic vernix.

FIG. 9 schematically illustrates simulated cells dispersed in a lipid matrix.

DETAILED DESCRIPTION

The file of this patent contains at least one drawing executed in color. Copies of this patent with color drawing(s) will be provided by the Patent and Trademark Office upon request and payment of the necessary fee.

A nontoxic simulated vernix composition, also referred to herein as synthetic vernix, contains a component of simulated cells and a component of at least one lipid. The inventive composition simulates the hydration, barrier, rheological, tactile, and other properties of native vernix. With respect to its hydration properties, native vernix provides both hydrophilic properties from the water associated with its cellular component, and hydrophobic properties from its lipid component. The inventive composition simulates hydrophilic properties of native vernix by hydrated emulsified water droplets, referred to as emulsified particles, that have the capability to retain, in a hydrated state, at least 65% ^(wt) water in the composition in their internal (water) phase. The inventive composition simulates hydrophobic properties of native vernix by a matrix of one or more lipids that are present in native vernix, in which the simulated cells are dispersed. In one embodiment, the lipids are substantially physiologic. The inventive composition thus retains or is capable of retaining water at a concentration that simulates native vernix, and transports water vapor at a rate that simulates native vernix. In one embodiment, the composition contains a component of at least one protein. This composition provides the barrier and hydration functions of natural vernix, but reduces or eliminates an immune response.

Native vernix, as used herein, encompasses vernix as it is obtained from a newborn, as well as vernix obtained from a newborn that has been rendered tractable, as described in U.S. Pat. Nos. 5,989,577; 6,113,932; 6,333,041; and U.S. patent application Ser. Nos. 09/850,844 (now U.S. Pat. No. 6,562,358); 10/241,184; 60/377,430 and 60/439,966; and PCT application Serial No. PCT/US03/13612 (now U.S. Patent application Ser. No. 10/512,933), each of which is expressly incorporated by reference herein in its entirety. An immune response, as used herein, is defined as immune system-provoked physical, biochemical, and/or molecular changes such as occurs in an individual challenged with a non-self protein, whether the symptoms of such a response are subclinical or clinical. A reduced immune response, as used herein, is any alleviation or diminution in kind, extent, duration, severity, etc. of the immune response. A protein, as used herein, also encompasses peptides and individual amino acids.

In the inventive composition, the cell component of native vernix is replaced by synthetic structures that perform the hydration functions of cells; these structures may be termed “simulated cells” or “synthetic cells”. The simulated cells in small particle form are mixed into a lipid matrix. The lipid matrix contains at least one commercially available lipid that is present in native vernix. The water soluble protein component is in a water phase that is bicontinuous with the simulated cell component. In embodiments where a protein component is present, it serves the role of the protein-based natural cells in native vernix. The protein component may be commercially available proteins, recombinant protein, synthetic proteins, etc. Proteins may be one or more of keratin, filaggrin, epidermal growth factor, surfactant associated proteins A, B, and/or D, and the individual amino acids comprising natural moisturizing factor (NMF). Hyaluronic acid may also be included. Proteins may be epidermally derived from a source other than native vernix.

Simulated cells are dispersed in a matrix of at least one lipid. Any or all of the following lipids may be used, each of which is found in native vernix in the concentration indicated, and each of which is available commercially (for example, Sigma, St. Louis Mo.): cholesterol esters, ceramides, triglycerides, cholesterol, free fatty acids, phospholipids, wax esters, squalene, wax diesters, and cholesterol sulfate.

In one embodiment, the lipid component of simulated vernix is in the range of about 5% to about 30%, and the protein component of simulated vernix is in the range of about 5% to about 30%, with the simulated cell/water component constituting the remaining concentration. In another embodiment, the lipid component is in the range of about 5% to about 30%, and the protein component may be up to about 30%. The absolute concentrations of lipid and protein components may vary, such that water is released slowly and maintains hydration by picking up moisture. The concentration of one or more of the lipid components is generally in the ranges shown to provide the 5%-30% lipid component of the simulated vernix, although the exact concentration is not critical: cholesterol esters about 20% to about 35% ceramide about 10% to about 20% triglycerides about 10% to about 20% cholesterol about 5% to about 10% free fatty acids about 5% to about 10% phospholipids about 5% to about 10% wax esters about 2% to about 8% squalene about 0.5% to about 5% wax diesters about 0.5% to about 6% cholesterol sulfate about 0.1% to about 3%

The composition of the lipid phase may be varied to provide the desired spreading characteristics and viscosity for the final composition. For example, a relatively higher wax content will produce a less spreadable, more viscous composition than a relatively lower wax content; a relatively higher free fatty acid and/or triglyceride content will produce a more easily spreadable, less viscous composition than a relatively lower free fatty acid and/or triglyceride content.

The protein component of natural vernix is provided by one or more protein from a source other than native vernix. For example, proteins may be synthesized using standard synthesis techniques known to one skilled in the art. Proteins may also be made by recombinant molecular techniques known to one skilled in the art. Proteins may also be obtained from commercial sources, for example Sigma (St. Louis Mo.). Thus, the protein component of the inventive composition may be from any source other than native vernix; the protein component may in fact contain one or more proteins from a natural source. As one example, cultured mammalian cells other than those derived from vernix may be used as a source of the protein component. As another example, non-human non-animal cellular materials may be used as a source of the protein component. As another example, surfactant protein D may be obtained from cow lung and used as a source of the protein component. As another example, keratins may be extracted from animal and human hair, wool, etc. and used as a source of the protein component.

In the inventive composition, the cellular component of native vernix is replaced with a component which mimics cells in performing a function of cells in native vernix. The “cellular” component, also referred to herein as simulated cells, hydrates a surface to which the inventive composition is applied. It does this by slowly releasing water and by transporting water vapor, as cells do in native vernix. The composition may endogenously perform this hydration function, or the composition may be engineered, modified, etc. to perform this hydration function. To replace the cellular component of natural vernix, any dispersed particle that is capable of controllably retaining and releasing water in a lipid environment may be used.

Phase stable water-in-oil emulsions in small particle form in a lipid matrix provided compositions that simulated native vernix. This is shown schematically in FIG. 9 where water droplets 10 exist in a lipid matrix 20, the water droplets 10 packaged in particles 30 as emulsions, cubosomes, etc. The synthetic vernix compositions substantially duplicated properties of native vernix. The emulsified particles performed the function of the biological cells in native vernix with respect to regulating water transport, permeability, barrier, water-loss, and other properties relating to water behavior. The emulsions effectively allowed the water to exist in droplets, i.e., packaged as droplets.

Emulsifying agents or emulsifiers are generally considered to be surface active agents or surfactants. While the term surfactant may refer to cleaning ability, in the case of the inventive compositions hydrophile-lipophile balance (HLB) is used to describe the nature of the emulsifier. The HLB of the emulsifier is selected so as to keep the water retained within the particular matrix of the formulation. If the HLB is too high, the emulsifier will dissolve in the water and therefore not keep the water as droplets within the lipid matrix.

HLB is a property represented on an arbitrary scale of 0-20 for non-ionic surfactants, with higher numbers indicating the most hydrophilic surface active agents, and lower numbers indicating the most hydrophobic surface active agents. The HLB of a nonionic surfactant is the approximate weight of ethylene oxide in the surfactant divided by 5. For example, polyoxyethylene derivatives of Spans (Tweens) have relatively higher HLB values in the range of about 9.6 to about 16.7, while sorbitan esters (Spans) have relatively lower HLB values in the range of about 1.8 to about 8.6. As other examples, the HLB of oleic acid is 1; the HLB of glyceryl monostearate (Span 80) is 3.8; the HLB of sorbitan monooleate (Span 20) is 4.3; the HLB of triethanolamine oleate is 12.0; the HLB of polyoxyethylene sorbitan is 15; the HLB of monooleate (Tween 80) polyoxyethylene sorbitan is 16.7; the HLB of monolaurate (Tween 20) sodium oleate is 18.0; the HLB of sodium lauryl sulfate is 40.

In the inventive composition, the HLB values of the emulsifying agents ranged from lower than 4 to about 6. In one embodiment, the HLB ranged from 3.8 to 6.0. In one embodiment, the HLB was about 3.8. These emulsifying agents provided a high internal phase (i.e., water phase) system, containing water as greater than about 65% ^(w/w) of its total volume, and yielded a water loss profile simulating native vernix.

In one embodiment the emulsifying agents were polyhydroxy hydrocarbons. In another embodiment the emulsifying agents were the non-ionic PEG-7 hydrogenated castor oil (Cremophore WO7®) (4% ^(w/w)), or polyglyceryl-4 isostearate and cetyl dimethicone copolyol and hexyl laurate (Abil WE09) (5% ^(w/w)). In another embodiment the emulsifying agents were cremophore WO7 (0.8% ^(w/w)) and cetyl dimethicone copolyol (2% ^(w/w)). In another embodiment the emulsifying agents were cetyl dimethicone copolyol (1% w/w) and Abil WE 09 (2% w/w). In another embodiment, the emulsifying agent was Abil WE 09 (2% w/w). In another embodiment the emulsifying agents were PEG-30 dipolyhydroxystearate (Arlacel P 135®, Uniqema, USA) (about 1.5% w/w) and sorbitan sesquioleate (Uniqema) (about 0.5% w/w). In another embodiment, the emulsifying agent is polyglyceryl-3-diisostearate (Unichema, Gouda, NL) and cetyl dimethicone copolyol. In another embodiment, the emulsifying agent is polyglyceryl-3-oleate (Danisco A/S, Copenhagen DK). In another embodiment, the emulsifying agent is polyglyceryl-4-isostearate (about 2.5% ^(w/w) to about 4% ^(w/w)) (ISOLAN GI 34, Goldschmidt, Mannheim, Del.). In another embodiment, emulsifying agent(s) is/are used with methyl glucose isostearate (about 2% ^(w/w) to about 5% ^(w/w)) (ISOLAN IS, Goldschmidt) as a co-emulsifier.

In one embodiment, the emulsifying agents were selected to minimize irritancy when the inventive composition was applied to a skin surface. As known to one skilled in the art, “low irritancy” materials cause little or no irritation in skin irritancy testing and among individuals with irritated skin, reactive skin conditions, or with susceptibility to skin irritation. Therefore, skin care product ingredients can be classified according to their effects on skin in standard testing. One irritancy test is the Human Patch Test. The materials to be evaluated are applied under an occlusive patch and left on the skin for up to 24 hours. Following application, the skin condition is evaluated by standard methods, such as dryness and erythema scoring using visual grading scales or instrumental measurement of skin barrier integrity and function. Low irritancy materials have relatively low Patch Test scores, e.g., 0.2-0.5 on a 04 scale, and/or cause substantially no irritation in a large population of healthy subjects. In one embodiment of the inventive composition, emulsifiers with low irritancy were selected over emulsifiers that yielded a stable product but that had the potential to cause low levels of irritation in irritated skin populations.

Physiologic lipids that are found in native vernix were incorporated in the formulation to constitute the lipid matrix. These included cholesterol and squalene (both from Sigma Aldrich, St. Louis, Mo.), ceramide III (Cosmoferm, NL), cholesterol sulfate (Acros Organics, Leicestershire, UK), linoleic acid (Henkel Corporation-Emery Group, Cincinnati Ohio), lanolin (Amerchol, Midland Mich.), triglyceride (e.g., capric caprilic triglyceride) (Henkel), and wax (e.g., beeswax, USP). Other physiologically acceptable lipids, such as Petrolatum® (CVS, Woonsocket, RI) and/or mineral oil, may be included in some formulations.

The inventive simulated vernix composition retained, or was capable of retaining, greater than about 65% water of the total composition by weight in its internal (water) phase. Additional components may assist in maintaining the emulsion, providing hydration, etc. For example, the water phase may contain electrolytes. In one embodiment, the water phase contained magnesium sulfate (The PQ Corp, Berwyn, Pa.) which binds water, assists in water release properties of the synthetic cell, and stabilizes the water-in-oil emulsion. In another embodiment, the water phase contained glycerin (Cognis, Cincinnati, Ohio). Glycerin has a high affinity for water and therefore assists with slow release of the water; it also binds water to the skin surface. In another embodiment, the water phase contained a preservative such as methylparaben and/or propylparaben (Chatham ISP Sutton Laboratories, Wayne N.J.).

The interaction of exogenous agents, such as water or other agents, with natural vernix is related to the nonpolar (dispersive) and polar (nondispersive) components of vernix and the critical surface tension (CST) of vernix. Water has a relatively high CST (72 dynes/cm). The hydrophobicity (i.e., relatively low CST) of vernix was unanticipated, because about 80% by weight of natural vernix is water. The nonpolar component (lipids) of vernix is substantially higher than the cellular polar component, and confers hydrophobicity to vernix because the lipid component is a continuous phase surrounding the cellular components with which water is associated. In comparison to a known hydrophobic material and skin protectant, petrolatum, which has an extremely high nonpolar component, the nonpolar component of natural vernix is only slightly lower. In addition, the CST of both vernix and petrolatum are comparable. As a result, application of vernix to a surface such as skin, either normal skin or compromised skin (for example, wounded, abraded, cut, punctured, etc.), protects the surface from the effects of water exposure.

A result of the low CST of vernix is that little interaction between vernix and hydrophilic liquids would be expected to occur. For example, there would be expected to be little interaction between a vernix-treated surface, such as skin or a substrate to which natural vernix has been provided, that is exposed to an exogenous hydrophilic liquid, such as water, saline, urine, etc. The low CST of vernix imparts a hydrophobic character to vernix with respect to these liquids, and hence vernix serves as a protectant against the effects of these liquids.

The water in native vernix is associated with cells, and the cells are embedded within the lipid material, thus, the lipid component presents vernix to the environment. However, if the lipid fraction is removed either partially or totally by exposure to hydrophobic agents, then the water rich fraction, such as cells, could be exposed to the environment. The inventive simulated vernix composition may be regulated to have a higher polar component to repel nonpolar agents. This composition may protect against nonpolar materials, even after the hydrophobic lipid components are modified through interaction with the environment.

Native vernix protects the developing skin from the deleterious effects of substances, such as water, urine, and feces, present in utero during gestation. The inventive composition may be applied to any biological surface whereby a surface energy of about 40 dynes/cm is beneficial for repelling exogenous agents. Thus, an effective amount of simulated vernix is that which achieves a surface free energy of about 40 dynes/cm, to a minimum of about 20 dynes/cm. For example, applying the inventive composition in an effective amount to the diaper area protects the skin from the damaging effects of fecal material. Feces contain protease and lipase enzymes which can damage the skin surface upon contact. Lowering the surface energy of this skin surface by applying the inventive composition protects the skin against contact with the water-containing feces.

Examples of simulated cells that may be used in the inventive composition include, but are not limited, to cubosomes, phospholipid liposomes, water-in-oil emulsified particles, nanoparticles, microparticles, colloidosomes, non-phospholipid liposomes (Catezomes®), cultured cells, etc. Each of these may be loaded with hydrophilic molecules to enhance hydration. Hydrophilic molecules include but are not limited to glycerin, lactic acid, pyrrolidone carboxylic acid, urocanic acid, and proteins which, as previously defined, include amino acids such as NMF. Each of these may also contain hyaluronic acid as an additional water binder and to control the viscosity of the composition.

Bicontinuous cubic phase liquid crystals (cubosomes) may be used. Cubosomes are dispersed nanostructured particles of cubic phase liquid crystals with controlled release properties. The surfactant assembles into bilayers that are twisted into a periodic, three-dimension periodic minimal surface, forming a tightly packed structure that is “honeycombed” with bicontinuous domains of water and lipid. This structure accommodates water-soluble, lipid-soluble, and amphiphilic molecules.

Three bicontinuous liquid crystal structures are common: P_(n3m) (D-surface), I_(a3d) (G-surface), and I_(m3m) (P-surface). These can be described in terms of nodal surfaces. Bicontinuous cubic phases are found in natural lipids, cationic and nonionic surfactants, and polymer systems, although the lipid most widely used to construct bicontinuous cubic phases is the monoglyceride monoolein. Following the phase diagram of Qiu and Caffrey, Biomaterials 21; 223 (1999), which is expressly incorporated by reference herein in its entirety, monoglycerides spontaneously form bicontinuous cubic phases upon the addition of water, are relatively insoluble (allowing the formation of colloidal dispersions of cubosomes), and are resistant to temperature changes.

Actives can be loaded by direct addition to melted lipid or water (i.e., before hydration), or by diffusion into the structure after it is formed. The structure generally maintains the efficacy of the actives and may help stabilize actives such as vitamins and proteins. The upper limit to loading lipid-soluble actives is typically about 10 wt. % (relative to the cubic phase), which is governed by the loss of cubic phase structure upon addition. The actives may be controllably delivered where diffusion is governed by the tortuous diffusion of the active through the “regular” channel structure of the cubic phase.

Cubosomes are thermodynamically stable and can last indefinitely provided there is no hydrolysis of the lipid. Colloidal dispersions of cubosomes may be stabilized by adding polymers. Cubosomes are fabricated from monoglycerol long chain saturated fatty acids, typically monoolein, and water. The ratio of monoolein/water may variable, for example, 60/40, 65/35, 70/30, 75/25, etc., such that it produces a cubosome phase. For example, if the composition contains 20% lipid and 5% protein, the cubosome/water component would constitute 75% of the total composition. Thus, the concentration of lipid in the total composition does not include the concentration of monoglycerol in the cubosome. A cubosome of 60% monoolein (C₁₇) 40% water gel may be prepared. Cubosomes are made by nucleation according to methods provided in Langmuir 17; 5748 (2001) which is expressly incorporated by reference herein in its entirety.

A first method of fabricating and stabilizing cubosomes involves high shear dispersion of bulk cubic liquid crystalline material into submicron particles. A second method involves simple mixing of two water-like solutions with minimal input of energy. This method results in cubosomes that are smaller and more stable than those produced by the first method. Monoolein, used to form cubic liquid crystals and essentially insoluble in water, is mixed with a hydrotrope which dissolves the lipid to create a water-like solution with a decrease of solubility. Cubosomes form spontaneously as long as the dilution trajectory (using a phase diagram of monoolein-ethanol-water) falls into a cubic phase-water miscibility gap. Besides monoolein, any lipid and hydrotrope combination which form cubic liquid crystalline material upon dilution may be used. Actives and stabilizers can be formulated into the lipid and/or hydrotrope to produce colloidally stabilized, controlled-release dispersions. A third method of spray drying produces dry powder cubosome precursors. Starch-encapsulated monoolein is produced by spray drying a dispersion of cubic liquid crystalline particles in an aqueous starch solution. Dextran-encapsulated monoolein is produced by spray drying an emulsion formed by an ethanol-dextran-monoolein-water system. The starch and dextran decrease powder cohesion during drying and act as a soluble colloidal stabilizer upon hydration of the powders. Both powders form colloidally-stable cubosomes with an average size of 0.6 μm upon addition to water. This method allows the surface state of the cubosomes to be tailored to particular uses. For example, cubosomes can be loaded with surfactant protein to provide anti-oxidant and anti-infective properties.

As previously stated, other types of vesicles or vehicles may be used as simulated cells. Phospholipid liposomes may encapsulate water and, optionally, also encapsulate water-soluble components. They may be coated with polyethylene glycol (PEG) to further enhance their hydrophilic properties.

Nanoparticles may also be used, for example, a polyvinyl alcohol hydrogel with a diameter in the range of about 500 nm to about 750 nm; a poly-N-isopropylacrylamide hydrogel (50 nm to 1 μm); a copolymer of poly(ethylene oxide)-poly(L-lactic acid); or poly(L-lactic acid) coated with poly(ethylene oxide).

Microparticles may also be used, such as poly(lactide-co-glycolide) and PEG-dextran conjugates in the range of about 400 nm to about 600 nm. A lipid multilayer which encapsulates water may also be used.

Colloidosomes may also be used. Colloidosomes are spherical shells of micron-sized colloidal particles that are formed when colloidal particles are introduced to emulsion droplet templates. They self-assemble on the surface of the droplets in order to minimize the total interfacial energy by eliminating part of the interface. When many particles self-assemble, the result is a six-fold two-dimensional crystalline structure. Colloidosomes are also selectively permeable, allowing sub-micron particles to diffuse in, but excluding larger micron-sized particles. They can also be made selectively permeable to particles of different sizes.

Non-phospholipid liposomes (Catezomes®, Collaborative Laboratories, Inc. East Setauket N.Y.), which are composed of fatty acid salts of quarternary amines may also be used. Their structure permits the incorporation of both hydrophilic and hydrophobic materials because the salt bond region of the molecule is hydrophilic and the alkyl chain region of the molecule is hydrophobic. Release of encapsulated material is controlled by regulating the ionic strength of the surrounding medium at the time of delivery to the skin.

Cultured cells may also be used. The cells may be disaggregated (using either chemical or mechanical disaggregation methods), engineered, loaded with hydrophilic molecules, etc. Any of these structures may also contain hyaluronic acid, which controls viscosity and also adds an additional water-binder.

In one embodiment, the inventive composition is applied to a physiologically acceptable support structure in a liquid state to form a film. It is presented as droplets which coalesce to form a film upon encountering the support. A film is defined herein as an interfacial surface covering, in either a liquid or a solid state, with temperature-dependant properties. Film-forming techniques include but are not limited to spraying, extruding, blowing, pouring, evaporating, coating and painting.

In an alternate embodiment, a preformed film of the inventive composition is applied to a physiologically acceptable support. The physiologically acceptable support is one that can withstand sterilization, preferably by standard sterilization techniques known to one skilled in the art such as exposing to gamma radiation, autoclaving, and so on. The support is not limited to a particular composition or configuration and, depending upon its use, may or may not be sterilized and may take various forms. In one embodiment, the film is used to enhance skin cell maturation and may be applied to structures such as filters, membranes, beads, particles, and so on. Similarly, the support structure is not limited to a particular state of matter and may be a solid, a semi-solid, a gel and so on. In one embodiment, the support consists of a nylon monofilament interpositional surfacing material such as N-terface® pads (Winfield Laboratories, Inc., Richardson Tex.), Biobrane II® (Sterling Drug Inc., New York N.Y.) or circular nylon filters of suitable porosity (Micron Separations Inc., Westboro Mass.). Other support materials, however, may also be used to practice the invention.

In another embodiment, the film of the inventive composition is used to promote wound healing and/or tissue repair. It may be applied to various materials for placement either in direct contact or indirect contact with an intact or compromised skin site requiring treatment, such as a wound, an abrasion, an ulcer, a burned area, a site of infection or irritation, a wart, etc. The support may be permeable to physical and/or chemical agents, and may take a variety of forms, depending upon its purpose and the extent of the area requiring dressing or treatment. The film may be applied to various synthetics such as thermoplastic films, blown films and breathable films, and various natural and synthetic fabric compositions such as woven, non-woven, spun, and stitched fabrics. The invention may be used in a variety of products, examples of which include wound dressings and coverings such as bandages, tapes, gauze, adhesive products applied for a short or long term to the skin, ostomy care products, hospital pads such as incontinent pads, absorbent pads, and examination pads, disposable and cloth diapers, and feminine hygiene products such as intralabial devices.

The inventive composition may be used therapeutically to promote skin growth, skin maturation, skin barrier formation, wound healing, skin flexibility, and tissue repair. It may also be used as a skin protectant to promote skin barrier formation, skin moisture retention, and skin flexibility.

The inventive composition has an overall neutral pH. The simulated cell component and/or added amino acids have a general acidic pH. The inventive composition has a viscosity profile, a rheology profile, penetrability, and water vapor transport properties that is substantially similar to native vernix.

As reported in U.S. patent application Ser. No. 09/850,844 (now U.S. Pat. No. 6,562,358), which is expressly incorporated by reference herein in its entirety, contact angle (degrees) data for fresh and 7-week old vernix and a petrolatum control are as follows: Fresh vernix 7-week old vernix Petrolatum Angle SD Angle SD Angle SD Benzyl Alcohol 21.8 2.9 19.6 1.6 34.4 3.0 Diiodomethane 36.2 2.1 31.8 1.8 38.4 2.2 Glycerol 74.3 1.9 74.2 2.3 79.1 2.1 Water 83.5 0.8 — — — —

The inventive composition having a protein component in the range of about 5% of the total composition to about 30% of the total composition, a lipid component in the range of about 5% of the total composition to about 30% of the total composition, and a water/simulated cell component constituting the remainder of the total composition, provides a composition having contact angles with the above agents which simulates those of native vernix. Specifically, the composition provides a contact angle with benzyl alcohol in the range of about 18.0 to about 24.7; a contact angle with diiodomethane in the range of about 30.0 to about 38.3; a contact angle with glycerol in the range of about 71.9 to about 76.5; and a contact angle with water in the range of about 82.7 to about 84.3.

Also as reported in U.S. patent application Ser. No. 09/850,844 (now U.S. Pat. No. 6,562,358), the Critical Surface Tension (CST) of fresh vernix and seven week old vernix was determined, along with that of a petrolatum control. The results are indicated in the following table: CST (dyne/cm) Fresh vernix (dynamic θ) 40.47 Fresh vernix (static θ) 38.65 7-week old vernix (static θ) 39.80 Petrolatum (static θ) 35.79

The synthetic vernix on a skin surface provides a CST of about 38 dynes/cm to about 41 dynes/cm and a CST greater than at least 36 dynes/cm.

CST is a “wettability index” that indicates the minimum value of surface tension needed for a liquid to spread completely (that is, have a contact angle of zero), on a particular surface material. Any liquid whose surface tension is equal to or less than the CST will make a zero contact angle (θ=0, Cos θ=1), and will completely spread on the surface, while any liquid having a surface tension greater than the CST will form drops with a finite contact angle.

The inventive composition having a protein component in the range of about 5% of the total composition to about 30% of the total composition, a lipid component in the range of about 5% of the total composition to about 30% of the total composition, and a water/simulated cell component constituting the remainder of the total composition, provides a composition having a CST which simulates those of native vernix.

Also as reported in U.S. patent application Ser. No. 09/850,844 (now U.S. Pat. No. 6,562,358), the Surface Free Energy (SFE) of the polar component of fresh native vernix was 1.48 dynes/cm, while petrolatum had almost no polar SFE (0.03 dynes/cm). These results indicate that the main component of the vernix surface free energy was dispersive, that is, nonpolar. The nonpolar component in vernix was slightly lower than that of petrolatum, which has an extremely low polar component.

The inventive composition having a protein component in the range of about 5% of the total composition to about 30% of the total composition, a lipid component in the range of about 5% of the total composition to about 30% of the total composition, and a water/simulated cell component constituting the remainder of the total composition, provides a composition having a SFE which simulates those of native vernix.

Also as reported in U.S. patent application Ser. No. 09/850,844 (now U.S. Pat. No. 6,562,358), native vernix provides barrier properties in the range of those of semipermeable films such as Exxaire®, Silon®, and Flexzan®, and provided an intermediate level of hydration. An intermediate level of hydration provided by the semi-permeable films produced the optimum environment for barrier repair to occur, compared to either a high or low level of hydration.

The inventive composition thus has barrier properties which simulate those of native vernix.

In one embodiment, the following general synthetic vernix composition A was used, with each component given in % weight (total of 100%): Composition A Lipid phase lanolin 1.5-2 squalene   3.2-5.8 linoleic acid   0.8-1.5 mineral oil   0-5 cholesterol   4-6 ceramide III   0.7-1.5 beeswax    3-4.2 capric/caprilic triglyceride   1-2 cholesterol sulfate   0-3 PEG30 dipolyhydroxystearate (Arlacel P135 ®) 1.5 sorbitan sesquioleate 0.5 Water phase methylparaben qs. magnesium sulfate 0.5 glycerin 2.5-5 water (deionized) 70.5-75

In another embodiment, the following synthetic vemix composition B was used, with each component given in % weight (total of 100%): Composition B Lipid phase lanolin 2 squalene 3.5 linoleic acid 0.8 cholesterol 6 ceramide III 1.5 beeswax 4.2 capric caprilic triglyceride 1 cholesterol sulfate 1 PEG30 dipolyhydroxystearate (Arlacel P135 ®) 1.5 sorbitan sesquioleate 0.5 Water phase methylparaben, propylparaben qs. magnesium sulfate 0.5 glycerin 2.5 water (deionized) 75

In another embodiment, the following synthetic vernix composition C was used, with each component given in % weight (total of 100%): Composition C Lipid phase lanolin 2 squalene 4 linoleic acid 1 mineral oil 5 cholesterol 4 ceramide III 1 beeswax 3 capric caprilic triglyceride 2 PEG30 dipolyhydroxystearate (Arlacel P135 ®) 1.5 sorbitan sesquioleate 0.5 Water phase methylparaben, propylparaben qs. magnesium sulfate 0.5 glycerin 5 water (deionized) 70.5

In another embodiment, the following synthetic vemix composition D was used, with each component given in % weight (total of 100%): Composition D Lipid phase lanolin 2 squalene 4 linoleic acid 1 mineral oil 3.5 cholesterol 5.5 ceramide III 1 beeswax 3 capric caprilic triglyceride 2 PEG30 dipolyhydroxystearate (Arlacel P135 ®) 1.5 sorbitan sesquioleate 0.5 Water phase methylparaben, propylparaben qs. magnesium sulfate 0.5 glycerin 5 water (deionized) 70.5

In another embodiment, the following synthetic vernix composition E was used, with each component given in % weight (total of 100%): Composition E Lipid phase lanolin 2 squalene 4 linoleic acid 1 mineral oil 3 cholesterol 5.5 ceramide III 1 beeswax 4.2 capric caprilic triglyceride 1.5 PEG30 dipolyhydroxystearate (Arlacel P135 ®) 1.5 sorbitan sesquioleate 0.5 Water phase methylparaben, propylparaben qs. magnesium sulfate 0.5 glycerin 5 water (deionized) 70.5

In another embodiment, the following synthetic vemix composition F was used, with each component given in % weight (total of 100%): Composition F Lipid phase lanolin 2-3 stearyl alcohol 3-4 beeswax 1-2 mineral oil 6-7 petrolatum 4-6 polyglyceryl-4-isostearate and cetyldimethicone 2 copolyol and hexyl laurate (Abil WE09) cetyl dimethicone copolyol 1 Water phase propylparaben qs. sodium chloride 0.7 glycerin 7 water (deionized) 70

In one embodiment of composition F, specific concentrations are 2.7% ^(wt) lanolin, 3.5% ^(wt) stearyl alcohol, 1.7% ^(wt) beeswax, 6.4% ^(wt) mineral oil, and 5% ^(wt) petrolatum.

Lanolin is classified chemically as a wax, being a complex mixture of naturally occurring esters and polyesters of thirty-three high molecular weight alcohols (principally sterols) and thirty-six fatty acids. It is 98% ester minimum, of which the fatty alcohols and fatty acids comprise an approximately 50/50 ratio. A typical composition of lanolin contains esters of sterols and triterpene alcohols (35.4%), esters of aliphatic alcohols (23.7%), monohydroxyesters of sterols and of triterpene and aliphatic alcohols (20.0%), di- and polyhydroxyesters and free diols (7.9%), free aliphatic alcohols (5.6%), free sterols (4.1%), free hydrocarbons (0.6%), free fatty acids (0.5%), and unknown components (2.2%).

In formulating the inventive compositions, the components of the lipid phase except squalene, Arlacel P135® and sorbitan sesquioleate in compositions A-E, and except Abil WE09 and cetyl dimethicone copolyol in composition F, were mixed. The mixture was heated on a water bath until it softened and became flowable. The temperature of the mixture ranged from about 70° C. to about 750C. The remaining components of the lipid phase were added with continued heating on the water bath until the mixture was completely melted. The temperature of the mixture ranged from about 70° C. to about 75° C.

The components of the water phase were mixed. The resulting mixture was heated on a water bath until the temperature of the mixture ranged from about 70° C. to about 75° C.

The water phase was then slowly added over about three to about five minutes to the melted lipid phase with vigorous stirring. After the water phase had been added and the mixture became homogeneous, the mixture was homogenized using a BioSpec Products homogenizer (Bartlesville Okla.) at about 15,000 rpm (set at 1 to 1.5 speed; the setting range is 1 to 5 to yield 5,000 rpm to 30,000 rpm) for about 4-5 minutes sufficient to form a viscous emulsion. The mixture was allowed to cool, then it was stored in a closed container under ambient conditions (i.e., about 20° C. to about 22° C.).

This procedure was used to prepare 10 grams of the inventive composition; hence, parameters such as the time of mixing may be varied for other amounts, as known to one skilled in the art.

The invention will be further appreciated with reference to the following examples.

EXAMPLE 1

Cubosomes of monoolein and water (60% monoolein, 40% water) are produced. The resulting cuboidal gel is further processed to produce a dispersion of smaller cubosome particles. The particles are mixed into the lipid phase of cholesterol esters (about 20% to about 35%), ceramide (about 10% to about 20%), triglycerides (about 10% to about 20%), cholesterol (about 5% to about 10%), FFA (about 5% to about 10%), phospholipids (about 5% to about 10%), wax esters (about 2% to about 8%), squalene (about 0.5% to about 5%), wax diesters (about 0.5% to about 6%), and cholesterol sulfate (about 0.1% to about 3%). The water phase of the cubosome may be loaded with hydrophilic molecules (glycerin, lactic acid, pyrrolidone carboxylic acid, urocanic acid, amino acids) to provide a source of water binding materials.

EXAMPLE 2

The synthetic vernix composition is prepared as in Example 1 using cubosomes of monoglycerol of long chain saturated fatty acids (e.g., C₂₂ chain length).

EXAMPLE 3

The synthetic vernix composition is prepared as in Example 1 replacing cubosomes with phospholipid liposomes, nonphospholipid liposomes, colloidosomes, nanoparticles, or microparticles.

Liposomes may be single or multiple lipid layers to encapsulate water, and coated on the outside with polyethylene glycol to provide additional water to the system. The water phase can also include water soluble components. Nanoparticles may be polyvinyl alcohol hydrogel, about 500 nm to about 750 nm in diameter. Nanoparticles may also be poly-N-isopropylacrylamide (pNIPAm) hydrogel; these are monodisperse hydrogel particles with sizes from 50 nm to 1 μm in diameter. Nanoparticles may further be poly(ethylene oxide)-poly(L-lactic acid) as a copolymer system. Nanoparticles of poly(L-lactic acid) may be coated with polyethylene oxide. Microspheres may be about 400 nm to about 600 nm in diameter containing poly(lactide-co-glycolide) to which polyethylene glycol dextran conjugates are added. Microspheres may encapsulate water to which a lipid multilayer has been added.

EXAMPLE 4

The synthetic vernix compositions may be prepared according to any of Examples 1-3, with hyaluronic acid added to provide additional water binding materials and to control viscosity of the composition.

EXAMPLE 5

Cubosomes with controlled release properties are prepared as described in J. Colloid Interface Science (2003) in press, except that natural moisturizing factor (NMF) is substituted for ketoprofen.

About 0.5 g monoolein is melted into the bottom of a 1000 ml glass cylinder. Surfactant and NMF are dissolved into the melt. Sufficient buffer is added to the monoolein to form the cubic phase liquid crystal. Once formed, an additional 50 ml buffer is added to the cylinder. An overhead propeller briskly stirs the solution above the liquid crystal. This arrangement has a one-dimensional diffusion profile with the diffusion of NMF through the gel as the rate-limiting step. Small aliquots of buffer are periodically removed, and the concentration of NMF is determined by spectrophotometric analysis at light of UV/visible wavelength.

EXAMPLE 6

Loaded solid lipid nanoparticles for topical application are prepared according to the method in Eur. J. Pharmaceutics Biopharm 49 (2000) 211, which is expressly incorporated herein by reference, except that NMF is substituted for vitamin A.

Solid lipid nanoparticles and nanoemulsions are prepared with 5% NMF (with respect to the lipid). Glyceryl monooleate was melted at 85° C. and NMF was added. The hot lipid phase was dispersed in a surfactant solution and a premix was formed using an ultra turrax (IKA, Staufen Germany). The premix was passed through a Lab 60 high pressure homogenizer (APV Gaulin Lübeck Germany). Two cycles at 500 bar and 85° C. were performed. Nanoemulsions were prepared in the same manner except that Miglyol 812 was substituted for glyceryl monooleate. In either nanoparticles or nanoemulsions, the final concentration of NMF was 0.5%.

EXAMPLE 7

Polymersomes, as described by Discher et al., Science (2002) 297: 967 which is expressly incorporated by reference herein in its entirety, are made from amphilic diblock copolymers. These polymers may be polyethyleneoxide-polyethyl-ethylene (EO₄₀-EE₃₇). The membrane is at least tenfold less permeable to water than the phospholipid bilayers of liposomes and is used to provide the water handling profile of natural vernix, specifically, regulation of water vapor transport and rate of water loss.

EXAMPLE 8

Poly (DL-lactide-co-glycolide) (PLGA) nanoparticles without surfactant are prepared by a dialysis method as described in J. App. Polymer Sci. 80 (2001) 2228, which is expressly incorporated by reference herein in its entirety. The PLGA nanoparticles are loaded with proteins, peptides, and/or amino acids, such as epidermal growth factor, NMF, etc., and water.

EXAMPLE 9

Poly (glutamic acid) poly(ethyleneglycol) hydrogels are prepared as described in J. Biomed. Mater. Res. 62 (2002) 14, which is expressly incorporated by reference herein in its entirety. Poly (glutamic acid) is the polymer backbone and poly (ethylene glycol) is the crosslinker. The hydrogels are synthesized using photo-initiated crosslinking chemistry and are loaded with proteins, peptides, and/or amino acids, such as epidermal growth factor, NMF, etc. and water.

EXAMPLE 10

Protein for controlled release is encapsulated in poly(lactide-co-glycolide) (PLGA) as described in Nature Biotechnology 18 (2002) 52, which is expressly incorporated by reference herein in its entirety. For PLGA microcylinder preparation, the protein, as previously defined, is suspended, with or without basic salt, in acetone-PGLA. The suspension is loaded into a syringe and extruded into silicone rubber tubing. The solvent extruded suspension is dried at room temperature and then under vacuum. For PLGA microsphere preparation, the protein in 10 mM phosphate buffer (pH 7.4), with or without basic salt, is added to a solution of PLGA/CH₂Cl₂ and homogenized at 10,000 r.p.m. and transferred to a 2% polyvinyl alcohol (PVA) solution. A water-in-oil-in-water emulsion is formed by vortexing. The particles are hardened in 0.5% PVA and are collected by centrifugation, washed, and lyophilized.

EXAMPLE 11

A highly porous polyglycolide is prepared using a solid state condensation reaction as described in Macromol. Chem. Phys. 200 (1999) 2221, which is expressly incorporated by reference herein in its entirety. Ground sodium chloroacetate is heated with constant stirring at either 160° C. or 180° C. Polyglycolide is washed with water to remove residual sodium chloroacetate and formed sodium chloride.

EXAMPLE 12

Evaporative water loss from the composition over time, which may alternatively be expressed as percent water retained in the composition over time, was evaluated. This was done by measuring the water in the composition at intervals over thirty minutes (FIG. 8A) and up to three hours (180 min) (FIGS. 8B and 8C) and calculating the percent of water for embodiments of the inventive composition (compositions B, C, D, E, F), native vernix, and the commercially available agents Eucerin® (Beiersdorf AG, Hamburg Germany) (a water-in-oil emulsion; the ingredients are listed as follows: water, petrolatum, mineral oil, ceresin, lanolin alcohol, methylchloroisothiazolinone, methylisothiazolinone), and Curel™ (Andrew Jergens Co., Cincinnati, Ohio) (an oil-in-water emulsion; the ingredients are listed as follows: water, glycerin, distearyldimonium chloride, petrolatum, isopropyl palmitate, cetyl alcohol, dimethicone, fragrance, sodium chloride, methylparaben, propylparaben).

To assess evaporative water loss from each of the compositions, the compositions were spread as a thin film (3.28 mg/cm²) on an aluminum pan (14 mm diameter) weighing dish and immediately weighed on a Cahn C-31 microbalance® (Cahn Instruments, Inc., Cerritos Calif.). This initial weight was designated W_(int). Gravimetric measurements were made every two minutes for the first thirty minutes, and every thirty minutes thereafter for three hours (180 min). The weighing dish and composition were then placed in a vacuum desiccator to remove all water in the composition. For samples in which the water content is unknown, the sample was weighed every day for up to seven to ten days or until a constant weight was obtained. This final weight was designated W_(end). Temperature and relative humidity of the room during the period of study were noted. If the relative humidity deviated from about 41% to about 45%, the experiments were performed in a controlled humidity chamber. A control material was used in all experiments to account for differences in environmental humidity (room conditions) from one experiment to another to allow data comparison. The difference between W_(int) and W_(end) was referred to as the total water content in the composition.

These data were used to calculate the initial percent water content in the composition and to obtain the percent water content at each time point. These data were plotted in terms of percent water content remaining in the composition over the period of time.

Native vernix provided the best water retention, both in its high water content and low rate of water loss. Native vemix contained about 81% ^(w/w) water at zero time. At 30 min, native vemix contained about 78% ^(w/w) water (about a 3% ^(w/w) loss in water). At 180 min, native vernix contained about 75% ^(w/w) water (about a 6% ^(w/w) loss in water).

Curel™ contained about 70% ^(w/w) water at zero time. At 180 min, Curel™ contained about 14% ^(w/w) water (about a 56% ^(w/w) loss in water).

Eucerin® contained about 39% ^(w/w) water at zero time. At 180 min, Eucerin® contained about 36% ^(w/w) water (about a 3% ^(w/w) loss in water).

Composition B contained about 73% ^(w/w) water at zero time. At 30 min, composition B contained about 67% ^(w/w) water (about a 6% ^(w/w) loss in water, calculation based on initial percent water). At 180 min, composition B contained about 59% ^(w/w) (about a 14% loss in water, calculation based on initial percent water).

Composition C contained about 70% ^(w/w) water at zero time. At 30 min, composition C contained about 50% ^(w/w) water (about a 20% ^(w/w) loss in water, calculation based on initial percent water). At 180 min, composition C contained about 33% ^(w/w) water (about a 37% loss in water, calculation based on initial percent water).

Composition D contained about 68% ^(w/w) water at zero time. At 30 min, composition D contained about 55% ^(w/w) water (about a 13% ^(w/w) loss in water, calculation based on initial percent water). At 180 min, composition D contained about 37% ^(w/w) water (about a 31% loss in water).

Composition E contained about 70% ^(w/w) water at zero time. At 30 min, composition E contained about 61% ^(w/w) water (about a 9% ^(w/w) loss in water, calculation based on initial percent water). At 180 min, composition E contained about 48% ^(w/w) water (about a 22% loss in water, calculation based on initial percent water).

Composition F contained about 70% ^(w/w) water at zero time. At 30 min, composition F contained about 57% ^(w/w) water (about a 13% ^(w/w) loss in water, calculation based on initial percent water). At 180 min, composition F contained about 39% ^(w/w) water (about a 31% loss in water, calculation based on initial percent water).

The rates of evaporative water loss from the composition over the first thirty minutes (from 0 to 0.5 hour), and then over the next two and one-half hours (from 0.5 to 3 hours), for each of the above compositions are summarized in the following table: Rate of Evaporative Water Loss 0.5 hr (30 min) Rate 0.5-3 hr (30-180 min) Composition change in % water Rate change in % water Native Vernix −5.2 −1.5 Eucerin ® −2 −0.5 Curel ™ −42 −13 composition B −12 −4 composition C −37 −7 composition D −24 −7 composition E −18 −5 composition F −23 −8

The rates were calculated from the data collected at intervals over 180 minutes (3 hours). This calculation was performed to quantify the shape of the curve of evaporative water loss, as shown in FIGS. 8A-C.

The data were obtained by performing regression analyses, one for the time from 0-0.5 hr (0-30 minutes), and the other for the time from 0.5-3 hrs (30-180 min). The rates were taken as the slopes of the regression lines expressed as change in % water in the composition/change in time. The first rate was the change over the first 0.5 hr, and the second rate was the change from 0.5-3 hrs. Therefore, the rate was change in % water/time in hrs. The rates were negative in sign because they represented a loss in water. A composition that lost no water would have a value of 0 (the numerator would be 0 and the denominator would be 0.5 or 2.5 hr).

For native vernix, the first and second rates were, respectively, −5.2% water in composition/hr and −1.5% water in composition/hr. For Eucerin®, the first and second rates were, respectively, −2% water in composition/hr and −0.5% water in composition/hr. Eucerin®) had a very slow evaporative water loss, similar to vernix, but it had a much lower starting water level, as is subsequently described.

The inventive compositions had a rate of evaporative water loss during 0-0.5 h from about −38% water in composition/hr up to 0% water in composition/hr, and a rate of evaporative water loss during 0.5-3 hr from about −8% water in composition/hr up to 0% water in composition/hr. In one embodiment, the upper limit for rate of evaporative water loss during 0-0.5 h was about −1% water in composition/hr, and the upper limit for rate of evaporative water loss during 0.5-3 hr was about −0.2% water in composition/hr.

Water vapor transport (WVT) through the compositions was also evaluated for the inventive compositions, as well as native vernix, Curel™, and Eucerin®. A modification of ASTM E96E procedure B expressly incorporated by reference herein, subsequently described, was used where a cream form of the composition was prepared in a film form and applied to a highly porous and permeable synthetic substrate at 37-38% relative humidity. The permeable substrate allowed the permeability characteristics of the composition to be determined without interference from the substrate. Water vapor transport through these films was determined as follows.

Specifically, four grams of distilled water was added to a hexagonal polystyrene disposable weighing dish (20 mm length×20 mm width×10 mm height). The dish was completely covered by a substantially highly permeable substrate of which N-terface® (Winfield Laboratories, Inc., Richardson Tex.) (50 mm×50 mm) is an example, which was glued with cyanoacrylate applied to the rim of the dish to form a watertight seal. The composition to be evaluated was uniformly applied to the outer surface of the substrate by spatula at a concentration of 25 mg/cm². The apparatus was maintained at the stated relative humidity. Testing under steady state conditions was performed after two hours of equilibration. Weight loss was measured at zero time, two hours, and four hours. The rate of weight loss, that is, the water vapor transport (WVT), was calculated for each composition in terms of weight per unit area per time (g/m²/h). Temperature and relative humidity of the room during the period of study were recorded.

The results of WVT at two hours are shown in the following table. Composition (25 mg/cm²) WVT (g/m²/h) native vernix 19.2 ± 4.9 Eucerin ®  2.6 ± 0.2 Curel ™ 72.0 ± 3.0 composition B 21.6 ± 3.0 composition C 20.0 ± 0.4 composition D 13.4 ± 0.4 composition E 13.2 ± 0.8 composition F 18.9 ± 1.3

For comparison, the water vapor transport for the dish alone (no substrate) was 150±4 g/m²¹ hr, and for the substrate alone was 132±9 g/m²/hr. The water vapor transport through vernix was about 19.2±4.9 g/m²/h. The water vapor transport through a water-in-oil emulsion (Eucerin®) was 2.6±0.2 g/m²/h. The water vapor transmission through an oil-in-water emulsion (Curel™) was 72.0±3.0 g/m²/h. Water vapor transport through composition B was 21.6±3.0 g/m²/h. Water vapor transport through composition C was 20.0±0.4 g/m²/h. Water vapor transport through composition D was 13.4±0.4 g/m²/h. Water vapor transport through composition E was 13.2±0.8 g/m²/h. Water vapor transport through composition F was 18.9±1.3 g/m²/h. Water vapor transport or transmission through the inventive synthetic vernix composition ranged between the percent water vapor transmission through a substantially highly permeable film, such as N-terface®, and the percent water vapor transmission through a substantially highly occlusive film, such as polytetrafluoroethylene (TEFLON ®) or Saran Wrap®. In one embodiment, water vapor transmission of the inventive synthetic vernix composition was between about 85% of the water vapor transmission through a substantially highly permeable film, and about 5% of transmission through a substantially highly occlusive film. That is, water vapor transmission through the synthetic vernix film was in the range that is at least 15% lower than water vapor transmission through a highly permeable film, and at least 5% higher than water vapor transmission through a highly occlusive film.

All compositions were stable at room temperature (about 20° C.) for at least two months without phase separation (i.e., they were phase stable), and without syneresis of the water (beading of water onto the sample surface). There was no change in color. The compositions thinned over time with slow evaporation of the internal phase water. Evaporation was accelerated if the compositions were not covered.

Freeze thaw data were obtained as a technical measure of composition stability. The compositions were stressed by freezing at −20±5° C. and thawing at +20±5° C. over three cycles. The freeze/thaw cycle testing was performed to demonstrate phase stability during temperature stresses, e.g., during shipment, storage, etc. Compositions were placed at a cold temperature (−20±5° C.), then placed at a warm temperature (+20±5° C.), then returned to a cold temperature. The cycle of cold to warm was repeated three times. The compositions did not separate or change viscosity, and were considered stable for storage, shipment, etc. under various weather conditions.

The inventive compositions had tactile properties similar to native vernix. Tactile properties were evaluated by individuals experienced in assessing tactile characteristics and using methods known to one skilled in the art, such as when the composition is rubbed between the fingers, and skin feel to which the compositions had been applied. To further characterize the feel of the compositions, the tactile properties were compared with tactile properties of standard oil-in-water and water-in-oil emulsions (data not shown). The inventive compositions were thick and viscous with characteristics of a cream, spreadable using a slight force such as that used to apply lotion or cream to the surface of skin to spread on skin, and did not leave a sticky feeling to the skin.

The compositions had Theological properties similar to native vernix. They did not flow under normal gravity. Characteristics observed during handling, spreading, etc were used to evaluate viscosity. The viscosity increased with increasing internal phase (water) because increasing the internal phase and reducing each droplet of internal phase resulted in packing of the composition. Increasing the internal phase (water phase) from about 70% ^(w/w) water to about 75% ^(w/w) water, for example, does not likely change the viscosity, because the compositions are already viscous. Increasing the internal phase (water phase) from about 30% ^(w/w) water to about 70% w/w water, however, resulted in a visually observable increase in viscosity. The viscosity of the inventive compositions was based on the amount of internal phase (water phase), and the type and amount of external phase (lipid).

The inventive compositions had an overall neutral pH. The compositions had a high and uniform water content (e.g., from greater than about 65% ^(w/w) to about 82% ^(w/w) water). They were highly viscous at room temperature (about 20° C. to about 22° C.). They were highly permeable to water, and only very slowly released water. The inventive compositions had a viscosity profile, a rheology profile, penetrability, tactile properties, permeability, and water vapor transport properties that were substantially similar to native vernix.

Exogenously applied physiologically compatible vernix removes soil from the skin with an effectiveness that is quantitatively at least equivalent to, and may be better than, commercial skin cleansers. Vernix on the skin surface interacts with exogenous cleansing agents such as soaps and/or surfactants, with subsequent flocculation and detachment, consistent with a function of vernix as an endogenous skin cleanser at birth. A soap, as used herein, is a mixture of sodium salts of long chain fatty acids, typically C₁₂ to C₁₈ fatty acids. A surfactant, as used herein, is a surface-active substance. Both soaps and surfactants are cleansing agents.

The cleansing aspects of isolated vernix and synthetic vernix were evaluated. Composition B was evaluated in cleansing assays of synthetic vernix. In one study, 10 mg of soiling material in the form of uniform black carbon particles (toner from a photocopier) were applied to normal adult volar skin (area=16 cm²). In some embodiments, a photographic image of the pre-soiled skin was recorded. This was followed by manual application and removal (gently wiping the area with a dry 4 in×4 in gauze pad) of about 12.5 mg/cm² of irradiated isolated native vernix or synthetic vernix, or selected skin cleansers (Pond's Cold Cream™ and Johnson & Johnson Baby Wash™). Removal of soil was quantified as a change in light intensity, using L-scale analysis of digital images of the cleansed skin. In another study, vernix was applied to human cadaver skin, with no vernix or vernix film thicknesses ranging from 2 mg/cm² to about 16 mg/cm². The skin sections were mounted in Franz diffusion cells and exposed to 0.25% ^(w/v) sodium lauryl sulfate (SLS), a common surfactant found in soap solutions. Following 24 hours of exposure, flocculation of vernix was measured spectrophotometrically as solution turbidity at 600 nm.

For cleansing assays using native vernix, vernix was collected from the skin surface of term newborn infants and stored at 4° C. until use. Samples contaminated with blood and/or meconium were discarded. Synthetic vernix was stored at room temperature until use.

Digital images of adult hand and volar forearm were recorded at 30× magnification using a Skin Surface Analyzer (Moritex USA, Inc.), which captures digital images between 10× through 700× magnification and can be operated using two different modes of illumination. One mode supplies light en faces, rendering precise surface detail. The second mode illuminates the skin via back-scattered light, resulting in polarization of the light source; this is useful when specular reflectance from the skin surface interferes with image analysis.

For the cleansing assay, 10 mg of the previously described soiling material was uniformly applied to pre-cleaned normal adult hand and volar forearm skin (area=16 cm²). This was followed by manual application and removal of 12.5 mg/cm² of a topical cleansing preparation, either irradiated native vernix, Pond's Cold Cream™, or Johnson & Johnson Baby Wash™, or, in another embodiment, 12.5 mg/cm² of synthetic vernix, native vernix, Pond's Cold Cream™, Johnson & Johnson Baby Wash™, water, or Aquaphor. All applications and removals used manual pressure under routine conditions. High resolution digital photographs were obtained with a Kodak DCS 420C digital camera before and after applying the soiling material, and after cleansing.

Digital images obtained during cleansing were analyzed to assess efficacy of vernix and the two commercially available topical cleansing preparations. Soil removal was quantified by processing the images in two ways. In one way, the change in light intensity was quantitated using Adobe Photoshop L-scale analysis. In the other way, a program was written using Matlab technical computing software (The Math Works, Natick Mass.), whereby the original digital image was first segmented into 16 equally sized regions and then converted to Gray scale. A threshold algorithm was performed on each region to distinguish between soiling material and background features of the skin. This process generated a black and white image that was used to calculate the percent of the region that was covered with the soiling material. Statistical comparisons between treatment groups were performed using one-way ANOVA.

Table 1 provides representative data from both the L-scale analysis and Gray scale analysis from one representative experiment. There surface evaluated was either clean (pre-treatment), fully soiled, fully soiled and treated with the indicated cleansing agent, evaluated after cleansing with the indicated agents (Aquaphor, Johnson & Johnson Baby Wash™, Pond's Cold Cream™, native vernix, water), or evaluated after cleansing with alcohol. TABLE 1 L-SCALE GRAY SCALE CLEANSING IMAGE Mean SD Mean SD AGENT pre-treatment 192 5 185 6 Aquaphor fully soiled 83 17 77 16 fully soiled plus 65 16 61 14 treatment post-treatment 174 7 166 8 cleaning post alcohol cleaning 154 7 145 7 pre-treatment 197 5 191 6 Johnson & Johnson Baby Wash ™ fully soiled 129 17 121 17 fully soiled plus 54 12 51 10 treatment post-treatment 182 6 175 7 cleaning post alcohol cleaning 196 4 190 4 pre-treatment 182 7 175 8 Pond's Cold Cream ™ fully soiled 108 14 99 14 fully soiled plus 77 19 71 17 treatment post-treatment 197 5 191 6 cleaning post alcohol 190 6 183 7 treatment pre-treatment 120 5 112 4 Native Vernix fully soiled 85 18 79 16 fully soiled plus 41 7 40 6 treatment post-treatment 135 5 126 5 cleaning post alcohol 120 5 112 4 treatment pre-treatment 193 5 187 6 Water fully soiled 53 16 50 14 fully soiled plus 96 25 89 23 treatment post-treatment 183 7 175 7 cleaning post alcohol 162 7 154 7 treatment

FIG. 1A demonstrates the cleansing capacity of native vernix. Digital images of the hand were recorded at 30× magnification using a Skin Surface Analyzer, as previously described. This set of images was obtained using en faces illumination of the skin. FIG. 1A shows the unsoiled skin surface. FIG. 1B shows the skin after application of the carbon particulate soiling material. The carbon particles remain lodged in the furrows and pores of the skin and in the sweat glands. FIG. 1C shows the soiled skin after application of native vernix, whereby no carbon particles are visible in any skin area, including furrows and pores.

FIG. 2 also demonstrates the cleansing capacity of synthetic vernix. The figures were obtained using the same conditions described previously, with the exception that volar forearm skin was used and a light source that provides illumination through the skin, rather than from above, was used. FIGS. 2A, 2B, and 2C show the unsoiled, carbon-soiled, and native vernix-cleansed skin, respectively. FIG. 2D shows an area of the soiled skin after washing the surface with a commercially available liquid hand soap instead of vernix. FIGS. 2E1-2E2, 2F1-2F2, and 2G1-2G2 show the unsoiled, carbon-soiled, and synthetic vernix-cleansed skin, respectively, in photographs using a light source that illuminates from above.

To quantitate the amount of soiling material on the skin surface, L-score values of volar forearm skin were obtained. Adult volar forearm was assessed using Adobe Photoshop L-scale analysis of digital images. With reference to FIG. 3, data were collected before soiling (baseline), after soiling material was manually rubbed into the skin (soiled), and after cleansing (cleaned). The cleansing treatments were either Aquaphor, Johnson & Johnson Baby Wash™, Pond's Cold Cream™, or vernix. The results are shown in FIGS. 3A, 3B, 3C, and 3D for tests with native vernix, and in FIGS. 3E, 3F, 3G, 3H, 3I, and 3J for tests with synthetic vernix compared to native vernix. The data demonstrate that all of the tested cleansing agents returned the skin to near baseline L-scale levels.

As shown in the following table, when using L-score data to compare baseline (pre-soiled) and cleaned volar forearm skin, one-way ANOVA revealed no statistically significant differences between the tested cleansing agents. TABLE 2 Comparison of Pre-Soiled and Cleaned Skin Using One-way ANOVA Cleaning Material Pond's Cold Johnson & Johnson Cream ™ Baby Wash ™ Native Vernix Mean 0.47% 1.19% 0.22% Standard Error of ±0.08 ±0.15 ±0.03 the Mean (SEM) Number of 48 48 48 Samples (N)

These data indicate that all of the topical cleansers adequately clean the skin surface. While Johnson & Johnson Baby Wash™ and Pond's Cold Cream™ are routinely used to cleanse the skin, the use of the natural vernix biofilm had not previously been reported.

FIG. 4 shows digital images of skin before soiling and after treatment with one of four cleansing agents: Aquaphor (FIG. 4A), Johnson & Johnson Baby Wash™ (FIG. 4B), Pond's Cold Cream™ (FIG. 4C), or native vernix (FIG. 4D). The images were obtained as previously described for FIG. 2. For each treatment, soiling material was visible on the skin after cleansing. Soiling material in pores was seen as punctate material, and soiling material on hair was seen as diffuse streaks. By visual inspection of the images, the native vernix treated skin appeared to have the most soiling material removed.

FIG. 5 quantitates the results from FIG. 4, and FIG. 5A quantitates the results from FIGS. 3E-3J as differences in L-scale scores before and after cleansing. The data in FIGS. 5 and 5A are (L value after cleansing −L value before soiling). A negative value indicated that skin retained some soiling material, with higher negative values indicating more soiling material retained. A positive value indicated that the skin was cleaner after the cleansing procedure. Approximate values for each treatment in tests using native vernix were as follows: Aquaphor −8; Johnson & Johnson Baby Wash™ +7; Pond's Cold Cream™−1; native vernix<−0.5; and water −11. These comparative data indicate that water and Aquaphor treatments leave the skin slightly “dirtier”; Johnson & Johnson Baby Wash™ leaves the skin “cleaner”; and Pond's Cold Cream™ and vernix remove the soiling material equally well.

The percent coverage determination is another measure of cleansing efficacy. One-way ANOVA of these data showed that native vernix cleansing resulted in a significantly less amount of soiling material residue, compared to Johnson & Johnson Baby Wash™ (p<0.05). No other significant differences between groups were observed.

As shown in FIG. 5A, approximate values for each treatment in tests using synthetic vernix in comparison to native vernix (FIGS. 3E-3J) for cleansing of skin were as follows: Aquaphor −2; synthetic vernix −5.8; Johnson & Johnson Baby Wash™ +2.1; Pond's Cold Cream™−0.9; native vernix −4; water −1.1.

FIG. 6 shows the conversion of a representative image obtained in the cleansing assay to its black and white counterpart for subsequent percent coverage calculation. FIGS. 6A1-6A6 show representative images of soiled skin and its black and white counterpart images before treatment with the indicated cleansing agent. FIGS. 6B1-6B6 show the respective images after treatment with the cleansing agent. The Matlab technical computing software was used to segment the original image into 16 equally sized regions. The resultant images are first converted to Gray scale, then a threshold algorithm is performed on the Gray scale images to distinguish between the soiling material and endogenous topographical features of the skin. This process generates the black and white image. The comparative cleansing abilities are shown graphically in FIG. 6C.

To determine the minimum concentration of test surfactant needed to maximally detach vernix, an evenly applied 12-mil coating (21 mg/cm²) of native vernix was spread onto a set of circular Gortex™ membranes (1.9 cm²) using an Accu-gate spreader. The coated membranes were gently rocked at 37° C. in 12 ml of either double-distilled water (blank) or a solution of sodium lauryl sulfate (SLS) diluted to 0.1% ^(w/v), 0.5% ^(w/v), or 1.0% ^(w/v). SLS is a surfactant commonly used to empirically model surfactant/skin interactions and is used in some skin cleansing formulations. After 18 hours, the turbidity of the SLS solutions was analyzed spectrophotometrically at 650 nm to assess the amount of vernix detachment. The results are shown in FIG. 7A.

In a separate experiment, surfactant-induced detachment of native vemix from the skin surface was assessed. Vernix was applied to human cadaver skin, with film thicknesses ranging from 2 to 16 mg/cm². The treated skin sections were mounted in Franz diffusion cells and exposed to 0.5% ^(w/v) SLS. Following 24 hours of SLS exposure, flocculation of vemix was spectrophotometrically measured as solution turbidity at 650 nm. The results are shown in FIG. 7B.

As shown in FIG. 7A, a concentration of about 0.5% ^(w/v) SLS achieved substantially maximum native vemix detachment. Concentrations of SLS up to about 0.5% ^(w/v) demonstrated increasing vemix detachment. Concentration of SLS greater than about 0.5% ^(w/v) demonstrated only minimally increasing vemix detachment. As shown in FIG. 7B, in the presence of 0.5% ^(w/v) SLS, quantitatively more vemix was removed with surfactant when thicker vernix films were used. This dose-dependent increase in detachment of vemix from either Gortex™ or human cadaver skin following SLS exposure indicated that commonly used cleansing surfactants remove vemix from the newborn during the first bath.

The data for native vernix demonstrated that all cleansing agents, including vernix, removed soil from the skin surface, as measured by a significant increase in the L-value using whole image analysis. Results among the cleansing agents were statistically indistinguishable. Analysis of magnified digital images indicated that vemix had better cleansing ability in deep pores, demonstrated by a significant reduction in the number of carbon particles at these sites. The data also demonstrated a dose dependent increase in turbidity at 600 nm following SLS exposure (p<0.05), indicating increasing detachment of vemix. No increase in turbidity was observed in control samples or in skin samples covered with equivalent amounts of petrolatum.

The data for synthetic vernix demonstrated that all the cleansing agents performed well and demonstrated the cleansing capacity for synthetic vernix. It was noted that there was inter-subject variability in the amount and depth of dermatogyphics, that spreading of soiling material and the skin's affinity for soil retention were affected by pore size and skin surface oiliness, and that hair and areas of hyperpigmentation may affect Matlab and L score results.

Among the clinical implications of the invention are the in vitro use of vernix as a skin cleansing material. Prenatally, vernix detaches into the amniotic fluid under the influence of pulmonary surfactant. This biological process is similar to self-cleaning (desquamation) of the stratum corneum. Vernix as an endogenous cleanser utilizes this cleansing function for optimal delivery room management during transition of the neonate, either full term or pre-term, to a nonsterile environment. The hydrophilic component of vernix aids in removing hydrophilic soils. The hydrophobic component of vernix aids in removing hydrophobic soils. The choice of an exogenous cleanser for the first bath may be tailored to detach soil and endogenous vernix, with vernix detachment either partial or complete as desired.

In one embodiment, vernix is removed from a newborn, collected, and stored at 4° C. The isolated vernix is thereafter used when cleansing the skin of the newborn from whom the vernix was obtained, and/or the mother of the newborn from whom the vernix was obtained. This may be continued for any cleansing procedure until the newborn and mother leave the hospital, or may be used for cleansing particular skin surfaces, either intact or compromised, or may be used until the isolated vernix is depleted.

In another embodiment, vernix is removed from a newborn. The isolated vernix is treated to render it physiologically compatible so that it may be applied to the skin of a different individual, that is, not the newborn from whom it was obtained or the mother of the newborn from whom it was obtained. The treatment is sufficient so that pathogens such as the human immunodeficiency virus, the hepatitis C virus, etc., and/or substances which may harbor pathogens such as blood, meconium, etc., are inactivated, killed, removed, etc. For example, vernix may be collected in a tube, covered, and treated by heat sterilization in an autoclave, by radiation exposure (light, x-rays, etc), or by other methods known to one skilled in the art. As further verification of the physiological compatibility of the isolated vernix, serological/immunological profiling may be performed on the newborn from whom vernix was isolated and mother. The isolated physiologically compatible vernix is then available for use to cleanse a skin surface of any individual, such as an individual whose skin is compromised, fragile, easily irritated, etc.

Other variations or embodiments of the invention will also be apparent to one of ordinary skill in the art from the above description. For example, a simulated cell component may be used as a vehicle to deliver agents to the skin surface to provide an anti-infective benefit, and also as a vehicle to deliver anti-oxidants such as Vitamin E to the skin. The composition may include other skin cleaning agents, and or other components such as emollients, humectants, etc. Thus, the forgoing embodiments are not to be construed as limiting the scope of this invention. 

1. A simulated vemix composition comprising a continuous lipid phase consisting essentially of physiologic lipids, and a hydratable water phase of simulated cells dispersed in the lipid phase, the hydratable water phase capable of retaining greater than about 65% ^(w/w) water of the total composition, said composition in a hydrated film form having a water vapor transmission rate that is between about 85% of the transmission rate through a substantially highly permeable film and about 5% of the transmission rate through a substantially highly occlusive film by a modified ASTM E96E procedure B, and having up to about 38% evaporative water loss from 0 h to 0.5 hr, and up to about 8% evaporative water loss from 0.5 hr to 3 hr.
 2. The composition of claim 1 wherein the simulated cells are at least one of cubosomes, phospholipid liposomes, nanoparticles, microparticles, colloidosomes, non-phospolipid liposomes, cultured cells, or emulsified particles.
 3. The composition of claim 1 wherein the simulated cells are water-in-oil emulsified particles.
 4. The composition of claim 3 further comprising an emulsifying agent having a hydrophile-lipophile balance (HLB) to provide water-in-oil emulsified particles.
 5. The composition of claim 4 wherein the HLB ranges between about 3 to about
 6. 6. The composition of claim 4 wherein the HLB ranges between about 3.5 to about 6.0.
 7. The composition of claim 4 wherein the HLB ranges between 3.8 to about 6.0.
 8. The composition of claim 4 wherein the emulsifying agent is selected from the group consisting of polyhydroxy hydrocarbons, non-ionic PEG-7 hydrogenated castor oil (Cremophore WO7®), polyglyceryl-4 isostearate and cetyl dimethicone copolyol and hexyl laurate (Abil WE09), PEG-30 dipolyhydroxystearate (Arlacel P 135®, sorbitan sesquioleate, polyglyceryl-3-diisostearate, polyclyceryl-3-oleate, and polyglyceryl-4-isostearate.
 9. The composition of claim 4 further comprising a co-emulsifier.
 10. The composition of claim 9 wherein the co-emulsifer is methyl glucose isostearate.
 11. The composition of claim 1 wherein the lipids comprise at least one of cholesterol esters, ceramide, triglycerides, cholesterol, free fatty acids, phospholipids, wax esters, squalene, wax diesters, or cholesterol sulfate.
 12. The composition of claim 4 wherein the emulsifying agent is at least one of PEG-30 dipolyhydroxystearate (Arlacel P 135®) or sorbitan sesquioleate.
 13. The composition of claim 1 wherein the water phase retains greater than about 65% ^(w/w) water of the total composition.
 14. A synthetic vernix composition comprising hydratable emulsified particles dispersed in a continuous lipid phase wherein the lipid is selected from at least one of lanolin, squalene, linoleic acid, cholesterol, ceramide, wax, triglyceride, at least one emulsifying agent selected from sorbitan sesquioleate or PEG30 dipolyhydroxystearate, the hydratable emulsified particles capable of retaining at least 65% ^(wt) water.
 15. The composition of claim 14 comprising about 1.5% ^(wt) to about 2% ^(wt) lanolin, about 3.2% ^(wt) to about 5.8% ^(wt) squalene, about 0.8% ^(wt) to about 1.5% ^(wt) linoleic acid, about 4% ^(wt) to about 6% ^(wt) cholesterol, about 0.7% ^(wt) to about 1.5% ^(wt) ceramide III, about 3% ^(wt) to about 4.2% ^(wt) beeswax, about 1% ^(wt) to about 2% ^(wt) capric/caprilic triglyceride, about 1.5% ^(wt) PEG30 dipolyhydroxystearate, and about 0.5% ^(wt) sorbitan sesquioleate.
 16. The composition of claim 14 comprising about 2% ^(wt) lanolin, about 3.5% ^(wt) squalene, about 0.8% ^(wt) linoleic acid, about 6% ^(wt) cholesterol, about 1.5% ^(wt) ceramide III, about 4.2% ^(wt) beeswax, about 1% ^(wt) capric caprilic triglyceride, about 1.5% ^(wt) PEG30 dipolyhydroxystearate, about 0.5% wt sorbitan sesquioleate, and about 1% ^(wt) cholesterol sulfate.
 17. The composition of claim 15 further comprising about 0% to about 3% cholesterol sulfate.
 18. The composition of claim 15 further comprising about 0% ^(wt) to about 5% ^(wt) mineral oil.
 19. The composition of claim 14 comprising about 2% ^(wt) lanolin, about 4% ^(wt) squalene, about 1% ^(wt) linoleic acid, about 5% ^(wt) mineral oil, about 4% ^(wt) cholesterol, about 1% ^(wt) ceramide III, about 3% ^(wt) beeswax, about 2% ^(wt) capric caprilic triglyceride, about 1.5% ^(wt) PEG30 dipolyhydroxystearate, and about 0.5% ^(wt) sorbitan sesquioleate.
 20. The composition of claim 14 comprising about 2% ^(wt) lanolin, about 4% ^(wt) squalene, about 1% ^(wt) linoleic acid, about 3.5% ^(wt) mineral oil, about 5.5% ^(wt) cholesterol, about 1% ^(wt) ceramide III, about 3% ^(wt) beeswax, about 2% ^(wt) capric caprilic triglyceride, about 1.5% ^(wt) PEG30 dipolyhydroxystearate, and about 0.5% ^(wt) sorbitan sesquioleate.
 21. The composition of claim 14 comprising about 2% ^(wt) lanolin, about 4% ^(wt) squalene, about 1% ^(wt) linoleic acid, about 3% ^(wt) mineral oil, about 5.5% ^(wt) cholesterol, about 1% ^(wt) ceramide III, about 4.2% ^(wt) beeswax, about 1.5% ^(wt) capric caprilic triglyceride, about 1.5% ^(wt) PEG30 dipolyhydroxystearate, and about 0.5% ^(wt) sorbitan sesquioleate.
 22. The composition of claim 14 wherein the water phase further comprises magnesium sulfate, glycerin, and at least one of methylparaben or propylparaben.
 23. The composition of claim 22 comprising about 0.5% wt magnesium sulfate and about 2.5% ^(wt) to about 5% ^(wt) glycerin.
 24. A synthetic vernix composition comprising hydratable emulsified particles dispersed in a continuous lipid phase wherein the lipid is selected from at least one of lanolin, stearyl alcohol, wax, mineral oil, or petrolatum; at least one emulsifying agent selected from cetyl dimethicone copolyol or polyglyceryl-4-isostearate and cetyl dimethicone copolyol and hexyl laurate (Abil WE 09), the hydratable emulsified particles capable of retaining at least 65% ^(wt) water.
 25. The composition of claim 24 comprising about 2% ^(wt) to about 3% wt lanolin, about 3% ^(wt) to about 4% ^(wt) stearyl alcohol, about 1% ^(wt) to about 2% ^(wt) wax, about 6% ^(wt) to about 7% ^(wt) mineral oil, about 4% ^(wt) to about 6% wt petrolatum, about 2% ^(wt) Abil WE 09, and about 1% ^(wt) cetyl dimethicone copolyol.
 26. The composition of claim 24 comprising about 2.7% ^(wt) lanolin, about 3.5% ^(wt) stearyl alcohol, about 1.7% ^(wt) wax, about 6.4% ^(wt) mineral oil, about 5% wt petrolatum, about 2% ^(wt) Abil WE 09, and about 1% ^(wt) cetyl dimethicone copolyol.
 27. The composition of claim 24 wherein the water phase further comprises glycerin, sodium chloride, and methylparaben.
 28. A method of treating a skin surface of an individual to remove a soiling material from the soiled skin surface, the method comprising applying a synthetic vernix composition to the soiled skin surface in an effective amount for removal of the soiling material, and thereafter removing the composition and soiling material from the skin surface, the synthetic vernix composition comprising a continuous lipid phase consisting essentially of physiologic lipids, and a hydratable water phase of simulated cells dispersed in the lipid phase, the hydratable water phase capable of retaining greater than about 65% ^(w/w) water of the total composition, said composition in a hydrated film form having a water vapor transmission rate that is between about 85% of the transmission rate through a substantially highly permeable film and about 5% of the transmission rate through a substantially highly occlusive film by a modified ASTM E96E procedure B, and having up to about 38% evaporative water loss from 0 h to 0.5 hr, and up to about 8% evaporative water loss from 0.5 hr to 3 hr.
 29. The method of claim 28 wherein the simulated cells are water-in-oil emulsified particles.
 30. A method of cleansing a soiled skin surface, the method comprising providing to the soiled skin surface a synthetic vernix composition simulating native vernix, the synthetic vernix composition comprising hydratable emulsified particles dispersed in a continuous lipid phase wherein the lipid is selected from at least one of lanolin, squalene, linoleic acid, cholesterol, ceramide III, wax, or triglyceride; and at least one emulsifying agent selected from sorbitan sesquioleate or PEG30 dipolyhydroxystearate, the hydratable emulsified particles capable of retaining at least 65% ^(wt) water.
 31. The method of claim 30 wherein the composition comprises about 1.5% ^(wt) to about 2% ^(wt) lanolin, about 3.2% ^(wt) to about 5.8% ^(wt) squalene, about 0.8% ^(wt) to about 1.5% ^(wt) linoleic acid, about 4% ^(wt) to about 6% wt cholesterol, about 0.7% ^(wt) to about 1.5% ^(wt) ceramide III, about 3% ^(wt) to about 4.2% ^(wt) beeswax, about 1% ^(wt) to about 2% ^(wt) capric/caprilic triglyceride, about 1.5% ^(wt) PEG30 dipolyhydroxystearate, and about 0.5% ^(wt) sorbitan sesquioleate. 